Conformations of cyclic 3',5'-nucleotides. Effect of the base on the synanti conformer distribution

The furanose and the phosphate rings of cyclic 3′,5′-nucleotides are locked in the ₄T³ and chair conformations respectively. The only variable which shows major conformational flexibility in these molecules is the rotation about the glycosyl bond which describes the orientation of the base relative to the sugar-phosphate bicyclic system. The glycosyl torsion angle has been analyzed for cyclic nucleotides with different purine and pyrimidine bases by use of conformational energy calculations. The results indicate that all the pyrimidine bases, U, T and C show a very strong energetic preference for the anti range of conformations. The calculations predict that among cyclic 3′,5′-purine nucleotides cyclic GMP and cyclic IMP favor the syn conformation to the anti by 95:5 and 70:30 respectively, while cyclic AMP shows a preference for the anti conformation to syn by 70:30. Thus the purines show a greater probability for the syn conformation than the pyrimidines in cyclic 3′,5′-nucleotides.     

Study of conformations of the adenosine phosphates. II: Adenosine tri- and diphosphate (ATP,ADP)

Using extended Hückel theory (EHT), a theoretical study of the preferred conformations of ATP and ADP are compared with the experimentally observed structures, as the second of a set of studies on the molecular conformations of AMP, ATP and ADP. Results show that EHT yields a minimum energy ATP configuration that corresponds to the observed structure when atoms from the crystal are included in the calculations. Eight torsional angles were examined for ATP and six for ADP with all atoms included in the calculations. Results indicate that torsional rotations involving the adenosine part of the molecule show well-defined local minima. The predominant feature of the pyrophosphate section, however, is a low energy profile enabling the molecule to adapt its conformation to the environmental conditions.     

Quantitative determination of conformations of flexible molecules in solution using lanthanide ions as nuclear magnetic resonance probes: application to adenosine-5'-monophosphate

A procedure is described here whereby the conformation, of a flexible molecule in solution can be found. The method depends on the study of the nuclear magnetic resonance spectrum of the molecule in the presence of perturbations due to specifically bound lanthanide cations. The magnetic perturbations are of two kinds: shifts of nuclear magnetic resonance spectral lines in the presence of cations such as Eu³⁺ and changes in relaxation rates of the nuclear magnetic resonance excitations in the presence of cations such as Gd³⁺. Suitable expressions are given for the relation between the magnitude of the perturbations and the geometry of the lanthanide complex in the absence of through-bond perturbations and for an axially symmetric system. It is proved that the spectral changes described here are not due to through-bond (contact) effects. The circumstances, in which the anisotropy of the magnetic susceptibility tensor, as seen in the nuclear magnetic resonance spectra, is of axial symmetry, are defined. The experimental systems described are of this kind. A computer program has been devised that searches for the conformations of the molecule which fit the nuclear magnetic resonance data.We outline here the principles of the method and how we have used a combination of relaxation and shift probes to obtain the conformation of adenosine-5′-monophosphate at pH 2. It is shown that a small family of closely related conformations fit the nuclear magnetic resonance data. These conformations are very similar to that of the crystal structure of AMP.     

Molecular conformational analyses of dehydroalanine analogues

The conformational preferences of dehydroalanine (ΔAla) were examined through ab initio calculations. The geometries of the minimum energy conformations for N-formyldehydro alanilamide and N-acetyl-N′-methylamide of dehydroalanine were determined by gradient optimization at the HF/6-31G* level, and correlation corrections were examined with MP2 single-point energy calculations. Furthermore, HF/3-21G ab initio geometry optimizations were performed on nine conformations of the model tripeptide N-acetyl-N′-methylamide of didehydroalanine. The results indicate that the C₅ is the lowest energy conformation at all levels of theory. However, the relative energy of the helix conformation decreases when the number of ΔAla residues in the peptide chain increases. On the other hand, significant variations of the geometry upon conformational change were observed for the three compounds investigated. These results permit to extract important conformationally dependent geometry trends. The results of this study were compared to x-ray diffraction data on single crystals of dehydroalanine-containing peptides. © 1995 John Wiley & Sons, Inc.     

Influence of ribose 2′-O-methylation on GpC conformation by classical potential energy calculations

Potential energy calculations were employed to examine the effect of ribose 2′-O-methylation on the conformation of GpC. Minimum energy conformations and allowed conformational regions were calculated for 2′MeGpC and Gp2′MeC. The two lowest energy conformations of 2′MeGpC and Gp2′MeC are similar to those of GpC itself. The helical RNA conformation (sugar pucker-C(3′)-endo, ω′ and ω,g^?g^?, bases-anti) is the global minimum, and a helix-reversing conformation with ω′, ω in the vicinity of 20°, 80° is next in energy. However, subtle differences between the three molecules are noted. When the substitution is on the 5′ ribose (Gp2′MeC), the energy of the helical conformation is less than that of GpC, due to favorable interactions of the added methyl group. When the substitution is at the 3′ ribose (2′MeGpC) these stabilizing interactions are outweighed by steric restrictions, and the helical conformation is of higher energy than for GpC. Furthermore, the statistical weight of the 2′MeGpC g^? g^? helical region is substantially less than the corresponding weight for Gp2′MeC. In addition, 2′MeGpC′s methoxy group is conformationally restricted to a narrow range centered at 76°. This group has a broadly allowed region between 50 and 175° in Gp2′MeC. These differences occur because the appended methyl group in 2′MeGpC is located in the interior of the helix cylinder, as it would be in polynucleotide, while it hangs unimpeded in Gp2′MeC. These findings suggest that 2′-O-methylation has both stabilizing and destabilizing influences on the helical conformation of RNA. For 2′MeGpC the destabilizing steric hindrance imposed by the nature of the guanine base dominates.     

Conformational Analysis of the 3′-5′-Cyclic Dinucleotide d<pApA> by Means of Molecular Mechanics

Abstract

The conformational properties of the cyclic dinucleotide d<(pApA)> were studied by means of molecular mechanics calculations in which a multiconformation analysis was combined with minimum energy calculations. In this approach models of possible conformers are built by varying the torsion angles of the molecule systematically. These models are then subjected to energy minimization; in the present investigation use was made of the AMBER Force field. It followed that the lowest energy conformer has a pseudo-two-fold axis of symmetry. In this conformer the deoxyribose sugars adopt a N-type conformation. The conformation of the sugar-phosphate backbone is determined by the following torsion angles: α⁺, β¹, γ⁺, ?¹ and ζ⁺. The conformation of this ringsystem corresponds to the structure derived earlier by means of NMR spectroscopy and X-ray diffraction. The observation of a preference for N-type sugar conformations in this molecule can be explained by the steric hindrance induced between opposite H3′ atoms when one sugar is switched from N- to S-type puckers. The sugars can in principle switch from N- to S-type conformations, but this requires at least the transition of γ⁺ to γ^?. In this process the molecule obtains an extended shape in which the bases switch from a pseudo-axial to a pseudo-equatorial position. The calculations demonstrate that, apart from the results obtained for the lowest energy conformation, the 180° change in the propagation direction of the phosphate backbone can be achieved by several different combinations of the backbone torsion angles. It appeared that in the low energy conformers five higher order correlations are found. The combination of torsion angles which are involved in changes in the propagation direction of the sugar-phosphate backbone in DNA-hairpin loops and in tRNA are found in the dataset obtained for cyclic d<(pApA)>. It turns out that in the available examples, 180° changes in the backbone direction are localized between two adjacent nucleotides.     

Dependence of Deformability of Geometries and Characteristics of Intramolecular Hydrogen Bonds in Canonical 2′-Deoxyribonucleotides on DNA Conformations

Abstract

The molecular structure and deformability (with respect to average geometry) of methyl ethers of canonical 2′-deoxyribonucleotides thymidine-5′-phosphate (mTMP), 2-deoxycytidine-5′- phosphate (mCMP), 2-deoxyadenosine-5′-phosphate (mAMP) and 2′-deoxyguanosine-5′- phosphate (mGMP) in different types of DNA have been calculated using B3LYP/cc-pvdz method. Comparison of energy at equilibrium conformations of nucleotides and conformations with torsion angles of backbone fixed to average values for different types of DNA reveals that incorporation of nucleotides to A-DNA macromolecules requires the minimum amount of deformation energy. Therefore, this type of DNA should be the least strained from viewpoint of intramolecular deformations of monomers. Modeling of environmental effects within the PCM approach reveals that the immersion of nucleotides in polar medium results in significant decrease of energy differences between anti conformers of all DNTs and syn conformers of mGMP This also leads to reduction by almost a half nucleotides' deformation energy facilitating formation of DNA macromolecule. Change of DNTs conformation causes switch between different types of intramolecular H bonds. Every type of DNA possesses unique set of intramolar hydrogen bonds in nucleotides.     

Stability and conformation of the dimeric HIV-1 genomic RNA 5′UTR

During HIV-1 assembly, the viral Gag polyprotein specifically selects the dimeric RNA genome for packaging into new virions. The 5′ untranslated region (5′UTR) of the dimeric genome may adopt a conformation that is optimal for recognition by Gag. Further conformational rearrangement of the 5′UTR, promoted by the nucleocapsid (NC) domain of Gag, is predicted during virus maturation. Two 5′UTR dimer conformations, the kissing dimer (KD) and the extended dimer (ED), have been identified in vitro, which differ in the extent of intermolecular basepairing. Whether 5′UTRs from different HIV-1 strains with distinct sequences have access to the same dimer conformations has not been determined. Here, we applied fluorescence cross-correlation spectroscopy and single-molecule Förster resonance energy transfer imaging to demonstrate that 5′UTRs from two different HIV-1 subtypes form (KDs) with divergent stabilities. We further show that both 5′UTRs convert to a stable dimer in the presence of the viral NC protein, adopting a conformation consistent with extensive intermolecular contacts. These results support a unified model in which the genomes of diverse HIV-1 strains adopt an ED conformation.     

Conformational stability in dinucleoside phosphate crystals. Semiempirical potential energy calculations for uridylyl-3'-5'-adenosine monophosphate (UpA) and guanylyl-3',5'-cytidine monophosphate (GpC)

Classical potential energy calculations were performed for the dinucleoside phosphates UpA and GpC. Two widely accessible low-energy regions of conformation space were found for the ω′, ω pair. That of lowest energy contains conformations similar to helical RNA, with ω′ and ω in the vicinity of 300° and 280°, respectively. All five experimental observations of crystalline GpC, two of ApU, and the helical fragment of ApApA fall in this range. The second lowest region has ω′ and ω at about 20° and 80°, respectively, which is in the general region of one experimentally observed crystalline conformer of UpA, and the nonhelical region of ApApA. It is concluded that GpC and ApU, which were crystallized as either sodium or calcium salts, are shielded from each other in the crystal by the water of hydration and are therefore free to adopt their predicted in vacuo minimum energy helical conformations. By contrast, crystalline UpA had only 1/2 water per molecule, and was forced into higher energy conformations in order to maximize intermolecular hydrogen bonding.     

Discrimination Between A-type and B-type Conformations of Double Helical Nucleic Acid Fragments in Solution by Means of Two-dimensional Nuclear Overhauser Experiments

Abstract

The solution structure of two double helical nucleic acid fragments, viz. r(CGCGCG) and d(CGCGCG), was probed by means of two-dimensional nuclear Overhauser effect spectroscopy. The two compounds were selected as models for the A-type and B-type double helical conformations, respectively, and it is shown that for each of the two model compounds the intensities of the NOE cross peaks between base- and H2′ (deoxy)ribose proteins are qualitatively in correspondence with the relative NOE intensities expected on basis of the supposed duplex conformations. Thus our results indicate that NOE-data can be used to differentiate between A- and B-type double helical conformations in solution.

Coupling constant data show that, except for G(6), all ribose rings in r(CGCGCG) adopt pure N (C3′-endo) conformations thereby manifesting that this molecule takes up a regular A-type double helical conformation in solution. In contrast, the deoxyribose rings in d(CGCGCG) retain conformational freedom in the duplex state, albeit that the N/S- equilibrium is biased towards the S (C2′-endo) sugar conformation. This finding indicates that in solution the B-DNA backbone is highly dynamic.     

Conformational studies on pyrimidine 5'-monophosphates and 3',5'-diphosphates. Effect of the phosphate groups on the backbone conformation of polynucleotides

In continuation of our studies on the effect of the base and the phosphate groups on the glycosyl and the sugar-phosphate backbone conformation, we have carried out semi-empirical potential energy calculations on the common 5′- and 3′5′-ribopyrimidine mono- and diphosphates by considering simultaneous rotations about the glycosyl (χ) and the C(4′)–C(5′) (ψ) bonds. This calculation provides an assessment of the nature and orientation of the base on the sugar–phosphate backbone conformation of nucleotides and polynucleotides. It is found that the attractive inetractions between the 5′-phosphate group and the base mutually stabilize the antiand the gauche-gauche (gg) conformations about χ and ψ, respectively, in 5′-ribopyrimidine nucleotides. The introduction of the 3′-phosphate group as in 3′,5′-ribopyrimidine diphosphates, still leaves the anti-gg as the most favored conformation with the important difference that the probability of occurrence of the anti, gauche-trans (gt) is how substantially increased. This is dependent to a large extent on the sugar conformation and to a lesser extent on the base. Uracil and thymine show a greater probability for the anti-gt than cytosine. The syn conformation is considerably less likely and its occurrence is also dependent on the base type, cytosine showing a lesser tendency than uracil and thymine. For the syn base, the most favourec conformation for ψ is gt, since gg is sterically disallowed and tg is destabilized by electrostatic repulsive interactions between the 3′ and 5′-phosphate groups. Thus, there is a striking correlation between the glycoysl and the backbone C(4′)–C(5′) bond conformations. The rest of the bonds of the backbone are considerable less dependent on the glycosyl conformation. These studies reveal that in poly-ribopyrimidine nucletides the majority of the nucleotide residues are expected to occur in the anti-gg conformation.     

Dynamic Refolding of OxyS sRNA by the Hfq RNA Chaperone

The Sm protein Hfq chaperones small non-coding RNAs (sRNAs) in bacteria, facilitating sRNA regulation of target mRNAs. Hfq acts in part by remodeling the sRNA and mRNA structures, yet the basis for this remodeling activity is not understood. To understand how Hfq remodels RNA, we used single-molecule Förster resonance energy transfer (smFRET) to monitor conformational changes in OxyS sRNA upon Hfq binding. The results show that E. coli Hfq first compacts OxyS, bringing its 5′ and 3 ends together. Next, Hfq destabilizes an internal stem-loop in OxyS, allowing the RNA to adopt a more open conformation that is stabilized by a conserved arginine on the rim of Hfq. The frequency of transitions between compact and open conformations depend on interactions with Hfqs flexible C-terminal domain (CTD), being more rapid when the CTD is deleted, and slower when OxyS is bound to Caulobacter crescentus Hfq, which has a shorter and more stable CTD than E. coli Hfq. We propose that the CTDs gate transitions between OxyS conformations that are stabilized by interaction with one or more arginines. These results suggest a general model for how basic residues and intrinsically disordered regions of RNA chaperones act together to refold RNA.     

Structure of a complex of catabolite gene activator protein and cyclic AMP refined at 2.5 A resolution

The structure of a dimer of the Escherichia coli catabolite gene activator protein has been refined at 2.5 A resolution to a crystallographic R-factor of 20.7% starting with coordinates fitted to the map at 2.9 A resolution. The two subunits are in different conformations and each contains one bound molecule of the allosteric activator, cyclic AMP. The amino-terminal domain is linked to the smaller carboxy-terminal domain by a nine-residue hinge region that exists in different conformations in the two subunits, giving rise to approximately a 30 degree rotation between the positions of the small domains relative to the larger domains. The amino-terminal domain contains an antiparallel beta-roll structure in which the interstrand hydrogen bonding is well-determined. The beta-roll can be described as a long antiparallel beta-ribbon that folds into a right-handed supercoil and forms part of the cyclic AMP binding site. Each cyclic AMP molecule is in an anti conformation and has ionic and hydrogen bond interactions with both subunits.     

Molecular Mechanics and Dynamics of an Abasic Frameshift in DNA and Comparison to NMR Data

Abstract

In a previous publication (Ph. Cuniasse, L.C. Sowers, R. Eritja, B. Kaplan, M.F. Goodman, J.A.H. Cognet, M. Le Bret, W. Guschlbauer and G.V. Fazakerley, Biochemistry 28, 2018 (1989), we determined by two dimensional NMR studies and molecular mechanics calculations the three-dimensional structure of a non-selfcomplementary oligonucleotide:

5′d(C1 P1 G2 P2 G3 P3 dr4 P4 G5 P5 G6 P6 C7)3′

3′d(G13P12C12PllCll P10 C10 P9 C9 P8 G8)5′

where dr, at the center of the first strand, is a model abasic site. In order to explain all the results arising from NMR measurements, we found that an equilibrium between two conformations was necessary. These conformations differ mainly by the sugar pucker of G5 which is C2′ endo or C3′ endo. The latter is stabilized by addition of counterions between phosphate residues P3 and P4.

In this paper, we have constructed systematically, all possible structures as a function of torsion angles delta of dr4 and of G5 by molecular mechanics in the presence or absence of counterions. Since these conformations were not forced with NMR distance measurements, this method allows detailed comparisons between all possible conformations and NMR data. Maps of contour lines of the potential energy, of fits to NMR distance measurements, and of helical twist as a function of torsion angles delta of dr4 and of G5 unravel the difficulties associated with the study of the G5 sugar pucker conformation equilibrium.

Sugar puckers and proton distances are very sensitive criteria to monitor molecular dynamics. Relying on these experimental criteria, we have tested many molecular dynamics preparation phases and we propose a new warm-up and equilibration procedure for molecular dynamics. Thus we show with a 290 ps molecular dynamic run that G5 is in conformational equilibrium and that all NMR data are well reproduced.     

The dynamics,structure, and conformational free energy of proline-containing antifreeze glycoprotein

Recent NMR studies of the solution structure of the 14-amino acid antifreeze glycoprotein AFGP-8 have concluded that the molecule lacks long-range order. The implication that an apparently unstructured molecule can still have a very precise function as a freezing inhibitor seems startling at first consideration. To gain insight into the nature of conformations and motions in AFGP-8, we have undertaken molecular dynamics simulations augmented with free energy calculations using a continuum solvation model. Starting from 10 different NMR structures, 20 ns of dynamics of AFGP were explored. The dynamics show that AFGP structure is composed of four segments, joined by very flexible pivots positioned at alanine 5, 8, and 11. The dynamics also show that the presence of prolines in this small AFGP structure facilitates the adoption of the poly-proline II structure as its overall conformation, although AFGP does adopt other conformations during the course of dynamics as well. The free energies calculated using a continuum solvation model show that the lowest free energy conformations, while being energetically equal, are drastically different in conformations. In other words, this AFGP molecule has many structurally distinct and energetically equal minima in its energy landscape. In addition, conformational, energetic, and hydrogen bond analyses suggest that the intramolecular hydrogen bonds between the N-acetyl group and the protein backbone are an important integral part of the overall stability of the AFGP molecule. The relevance of these findings to the mechanism of freezing inhibition is discussed.     

On the multiple-minima problem in the conformational analysis of polypeptides. II. An electrostatically driven Monte Carlo method--tests on poly(L-alanine)

A new approach to the multiple-minima problem in protein folding is presented. It is assumed that the molecule is driven toward the native structure by three types of mechanism. The first one involves an optimization of the electrostatic interactions, whereby the molecule evolves toward conformations in which the charge distribution becomes energetically more favorable. The second mechanism involves a Monte Carlo–energy minimization approach, and the third one is a backtrack mechanism that acts in the opposite direction, increasing the energy—the third type of movement provides a means to perturb the molecule when it is trapped in a stable but energetically unfavorable local energy minimum. This paper describes the implementation of a model based on these mechanisms, and illustrates its effectiveness by computations on different arbitrary starting conformations of a terminally blocked 19-residue chain of poly(L -alanine) for which the global minimum apparently corresponds to the right-handed α-helix. In all cases, the global minimum was attained, even when the starting conformation was a left-handed α-helix. In the latter case, the trajectory of conformations passed through partially melted forms of the left-handed α-helix (because of electrostatic defects at the ends), and then through the formation of structures leading to the more stable right-handed α-helix.     

The crystal structure of a major metabolite of thyroid hormone: 3,3′,5′-triiodo-L-thyronine

Two independent conformations of the thyroinactive thyroid hormone metabolite, 3,3′,5′-triido-L-thyronine (rT₃) were determined by X-ray diffraction methods. The conformations show significant difference in the lettering geometry when compared with those of the thyroactive thyroxine (T₄) and 3,5,3′-triido-L-thyronine (T₃). The diphenyl ether conformation of the two conformers of rT₃ is an anti-skewed one, in which the torsion angels, φ (C5-C4-O4-Cl′) are 8° and ?6°, and φ′ are 86° and 87°. This conformation is in contrast to a twist-skewed one of T₄ and T₃. The difference in the binding abilities between T₄, T₃ and rT₃ to thyroxine binding carrier proteins in serum or to a nuclear receptor protein may be explained by the characteristics solid-state conformations of these metabolites.     

Study of conformations of the adenosine phosphates. I: Adenosine monophosphate (AMP)

Theoretical studies of the AMP molecule are made in a free and isolated environment with extended Mickel theory (EHT) using the experimentally observed bond lengths and angles, and the experimentally observed torsion angles as a starting conformation. Four torsional degrees of freedom were assumed and all AMP atoms were included in the calculations. Results show that the AMP structure corresponds to an EHT minimum energy configuration when the molecule is isolated from the crystal atoms. This is in contrast with results reported for ATP in the succeeding paper and is attributed to the fact that AMP is crystallized as a free acid. A global minimum, corresponding to a more open structure, is calculated to be more stable than the crystalline form and is lower in energy by 0·05 eV.     

Conformational analysis of the 3'-5'-cyclic dinucleotide d less than pApA greater than by means of molecular mechanics

The conformational properties of the cyclic dinucleotide d less than pApA greater than were studied by means of molecular mechanics calculations in which a multiconformation analysis was combined with minimum energy calculations. In this approach models of possible conformers are built by varying the torsion angles of the molecule systematically. These models are then subjected to energy minimization; in the present investigation use was made of the AMBER Force field. It followed that the lowest energy conformer has a pseudo-two-fold axis of symmetry. In this conformer the deoxyribose sugars adopt a N-type conformation. The conformation of the sugar-phosphate backbone is determined by the following torsion angles: alpha +, beta t, gamma +, epsilon t and zeta +. The conformation of this ringsystem corresponds to the structure derived earlier by means of NMR spectroscopy and X-ray diffraction. The observation of a preference for N-type sugar conformations in this molecule can be explained by the steric hindrance induced between opposite H3' atoms when one sugar is switched from N- to S-type puckers. The sugars can in principle switch from N- to S-type conformations, but this requires at least the transition of gamma + to gamma -. In this process the molecule obtains an extended shape in which the bases switch from a pseudo-axial to a pseudo-equatorial position. The calculations demonstrate that, apart from the results obtained for the lowest energy conformation, the 180 degrees change in the propagation direction of the phosphate backbone can be achieved by several different combinations of the backbone torsion angles. It appeared that in the low energy conformers five higher order correlations are found. The combination of torsion angles which are involved in changes in the propagation direction of the sugar-phosphate backbone in DNA-hairpin loops and in tRNA, are found in the dataset obtained for cyclic d less than pApA greater than. It turns out, that in the available examples, 180 degrees changes in the backbone direction are localized between two adjacent nucleotides.     

Conformational energy calculations of enzyme-substrate complexes of lysozyme. I. Energy minimization of monosaccharide and oligosaccharide inhibitors and substrates of lysozyme

Conformational energy calculations were performed on monosaccharide and oligosaccharide inhibitors and substrates of lysozyme to examine the preferred conformations of these molecules. A grid-search method was used to locate all of the low-energy conformational regions for N-acetyl-β-D -glycosamine (NAG), and energy minimization was then carried out in each of these regions. Three stable positions for the N-acetyl group have ben located, in two of which the plane of the amide unit is normal to the mean plane of the pyranosyl ring. Nine local energy minima were located for the —CH₂OH group. The positions of the two vicinal cis —OH groups are determined predominantly by interactions with either the —CH₂OH or the N-acetyl group. The most stable conformations of β-N-acetylmuramic acid (NAM) were determined from the study of the low-energy conformations of NAG. In the two stable orientations for the D -lactic acid side chain, the O—C—C′ plane (C′ being the carbon atom of the terminal carboxyl group) was found to be normal to the mean plane of the pyranosyl ring. The low-energy positions for the COOH group of NAM are determined mainly by interactions with neighboring groups. The conformational preferences of the α-anomers of NAG and NAM were also explored. The calculated conformation of the N-acetyl group for α-NAG was quite close to that determined by X-ray analysis. Two of the three lowest energy conformations of α-NAM are similar to the corresponding conformations of the β-anomer. A third low-energy structure, which has a hydrogen bond from the NH of the N-acetyl group to the C?O of the lactic acid group, corresponds very closely to the X-ray structure of this molecule. The preferred conformations of the disaccharides NAG–NAG, NAM–NAG and NAG–NAM were also investigated. Two preferred orientations of the reducing pyranosyl ring relative to the nonreducing ring were found for all of these disaccharides, both of which are close to the extended conformation. In one of these conformations, a hydrogen bond can form between the OH group attached to C₃ of the reducing sugar and the ring oxygen of the preceding residue. Each conformation can be stabilized further by a hydrogen bond between the CH₂OH (donor) of residue i + 1 and the C?O of residue i (acceptor). The interactions that determine conformations for all oligosaccharides containing both NAG and NAM are shown to be exclusively intraresidue and nearest neighbor interactions, so that it is possible to predict all stable conformations of oligosaccharides containing NAG and NAM in any sequence.